Known as the 3TrinsRGB+1c, it’s available both assembled and in kit form. It’s probably best to start with the manual. Synthesis is achieved through the use of a HEF40106 hex inverting buffer – a cheap and readily available part that nonetheless provides for excellent results. Video can be switched between RGB oscillators and a series of inputs, and there are various controls to create those classic scrolling effects and other visual oddities.

Additionally, a series of connections to the underlying circuitry are broken out on a header connector. This allows for extra modules to be plugged in, and several designs are available to expand the unit’s capabilities.

Analog video isn’t used so much on a day-to-day basis anymore, but it’s a great technology to tinker and experiment with. We’ve seen some of [gieskes] experiments in this arena before, too – like this Arduino video sampler. Video after the break.

If you’ve ever been to Amsterdam, you know there are plenty of canals and, therefore, plenty of bridges. Next year, a unique pedestrian bridge in the old city center will go into service. The stainless steel bridge will be 3D printed and also embed a number of sensors that will collect data that the printer — MX3D — and their partners Autodesk, the Alan Turing Institute, and the Amsterdam Institute for Advanced Metropolitan Studies, hope will help produce better 3D printed structures in the future. The bridge will cross the Oudezijds Achterburgwal which is near the city’s infamous red light district.

Since the bridge matches exactly with the model used to print it, scientists hope to be able to map the sensor data to a virtual twin of the bridge very easily. You can see a few videos about the bridge’s construction below. This month, during Dutch Design Week, visitors had a chance to walk across the bridge to generate some of the first live datasets.

When you think about singer-songwriters, the name Bob Dylan might come to your mind. You might think about Jeff Buckley, you might think about Hank Williams, Springsteen, David Bowie, or Prince. You’d be wrong. The greatest singer-songwriter of all time is Tiny Tim, the guy who looks like Weird Al traveled in time and did a cameo in Baker-era Doctor Who. Tiny Tim had the voice of an angel, because Mammon and Belial were angels too, I guess. Tiny Tim is also the inspiration behind the current resurgence of the ukulele, the one thing keeping the stringed instrument industry alive today.

The first goal of this project was to build a functional ukulele out of a Game Boy case. This was simple enough — the neck was 3D printed, the bridge was screwed in, and the case of the Game Boy was reinforced with some PCB material. So far, this is nothing new; you can get a model for a 3D printed ukulele on Thingiverse.

The second goal of this project was to make this ukulele into a chiptune machine. This means designing a pickup for the strings, and since these are nylon you’re not going to do a magnetic pickup on a ukulele. The first solution was an IR reflectance sensor, which worked but had too high of a power draw. The better solution was a standard flex pressure sensor, which worked well enough. This signal is distorted into a square wave that gives a surprisingly Game Boy-like sound. You can check out the video demo below.

You’ve no doubt heard about the “hardware implants” which were supposedly found on some server motherboards, which has led to all sorts of hand-wringing online. There’s no end of debate about the capabilities of such devices, how large they would need to be, and quite frankly, if they even exist to begin with. We’re through the looking-glass now, and there’s understandably a mad rush to learn as much as possible about the threat these types of devices represent.

EEPROM (left) can be edited to enable SMBus access on this card (header to the right)

[Nicolas Oberli] of Kudelski Security wanted to do more than idly speculate, so he decided to come up with a model of how an implanted hardware espionage device could interact with the host system. He was able to do this with off the shelf hardware, meaning anyone who’s so inclined can recreate this “Hardware Implant Playset” in their own home lab for experimentation. Obviously this is not meant to portray a practical attack in terms of the hardware itself, but gives some valuable insight into how such a device might function.

One of the most obvious attack vectors for hardware implants is what’s known as the Baseboard Management Controller (BMC). This is a chip used on modern motherboards to allow for remote control and monitoring of the system’s hardware, and promises to be a ripe target for attackers. There are a few sideband channels which can be used by the BMC chip to talk to other chips. To keep things simple [Nicolas] focused on the older I2C-derived SMBus (rather than the newer and more complex NC-SI), demonstrating what can be done once you have control of that bus.

Only problem was, he didn’t have a motherboard with a BMC to experiment with. After a little research, the answer came in the form of the Intel EXPI9301CTBLK network card, which features the 82574L SMBus chip. This allows for experimenting with a subset of SMBus functionality on any machine with a PCI-E slot. Even better, the card has an SMBus header on the top to plug into. [Nicolas] describes in detail how he enabled the SMBus interface by modifying the card’s EEPROM, which then allowed him to detect it with his HydraBus.

With the hardware setup, the rest of the write-up focuses on what you can do with direct control of SMBus on the network card. [Nicolas] demonstrates not only creating and sending Ethernet packets, but also intercepting an incoming packet. In both cases, a running instance of tcpdump on the host computer fails to see the packets even exist.

He goes on to explain that since SMBus is very similar to I2C and only requires four wires, the techniques shown could easily be moved from the Hydrabus dev board used in the demo, to a small microcontroller like the ATtiny85. But you would still need to find a way to add that microcontroller directly onto the network card without it being obvious to the casual observer.

The command line. You either love it or hate it, but if you do anything with a Unix-like system you are going to have to use it eventually. You might find marker — a system billed as a “command palette for the terminal” — a useful program to install. We couldn’t decide if it was like command history on steroids or more of a bookmark system. In a way, it is a little of both.

Your history rolls off eventually and also contains a lot of small commands (although you can use the HISTIGNORE variable to ignore particular commands). With marker, you save specific commands and they stay saved. There are no extra commands nor do the ones you save ever roll off.

Of course, you could just make a shell script or an alias if that’s all there was to it. Marker lets you add a description to the command and then you can search through the commands and the descriptions using a fuzzy incremental search. In addition, you can put placeholders into your command lines that are easily replaced. There are some built-in commands to get you started and the same bookmarks will work in bash and zsh, if you use both.

There’s something common to every form of music. Nearly every musical tradition, from western art music, to Indonesian folk music makes use of a pentatonic scale. This is just a major scale without fourth and seventh scale degrees, or just playing the black keys on a piano. It’s the one scale everybody knows, and forms the basis of every school of thought for music education. Noodling over the pentatonic scale is what all the cool guys do in Guitar Center. It’s absolutely the foundation of all music.

The hardware for this build is an Adafruit Metro Mini, or basically an Arduino with an ATMega328. This generates three channels of audio, two square waves — one each for the keyboard and bass accompaniment — and a pseudo-random noise drum beat. The keys are 3D printed, and the enclosure is CNC’s acrylic.

Most educational music toys out there have a few additional bits to make composing music easier. The Pentasynth is no exception, with a button that adds a drum beat, a button that adds a bassline, and a switch that makes the keyboard major or minor. It’s a great idea, and you can check out a video of the Pentasynth in action below.

The field of soft robotics sure seems a lot less mature than your standard servo motor and metal framed robot arms. Maybe that’s because building a robot to flex is harder, and maybe it’s because the best methods of constructing soft robotics have only been around for a decade or so. Maybe, though, it’s because it’s hard to control air.

For this week’s Hack Chat, we’re going to be discussing Air Hacking with [Amitabh Shrivastava]. [Amitabh] is a grad student at ITP, NYU studying creative technology, where he makes interactive art, tools for research, and experiments with various materials. Lately he has been developing Programmable-Air, a pneumatic controller for soft robotics. We’ve seen his work at ThiMaker Faire, and it’s an awesome project in this year’s Hackaday Prize.

In this chat we will be talking about DIY soft robotics. Soft robotics is a growing field with a lot of low hanging fruits within grasp of the hobbyist maker. In addition to sharing experience and resources about building your own soft robots, we will talk about actuation! Tune in to see how you can use pneumatics in your next project.

During this week’s Hack Chat, we’ll be discussing:

Pneumatics

Programmable Air

Soft Robotics

Methods of adding pneumatics to your project

You are, of course, encouraged to add your own questions to the discussion. You can do that by leaving a comment on the Air Hacking Hack Chat and we’ll put that in the queue for the Hack Chat discussion.